KR20160020520A - Composite material for fuel cell, manufacturing method of composite material for fuel cell, and fuel cell - Google Patents

Abstract

Provided is a composite material for a fuel cell capable of preventing deterioration of ion conduction performance of a solid electrolyte layer when an electrolyte-anode laminate is simultaneously fired, and capable of enhancing power generation performance of a fuel cell. 1. A composite material (1) for a fuel cell comprising a solid electrolyte layer (3) and an anode layer (2) laminated on the solid electrolyte layer, wherein the solid electrolyte layer has a perovskite structure of A Wherein the site is composed of an ion conductor formed of at least one of barium (Ba) and strontium (Sr) and partially substituted with a trivalent rare earth element in the tetravalent cation of the B site, An electrolyte component having the same composition as that of the solid electrolyte layer, and a nickel (Ni) catalyst, and an additive including at least a boundary portion with the solid electrolyte layer and a rare earth element.

Description

Technical Field [0001] The present invention relates to a composite material for a fuel cell, a method for manufacturing a composite material for a fuel cell,

The present invention relates to a composite material for a fuel cell, a method for producing a composite material for a fuel cell, and a fuel cell. Specifically, the present invention relates to a composite material for fuel cells and the like capable of enhancing the power generation performance of an electrolyte layer in a solid oxide fuel cell.

A solid oxide fuel cell (hereinafter referred to as " SOFC ") comprises an electrolyte-electrode laminate in which an anode layer and a cathode layer are formed on both sides of a solid electrolyte layer. In order to reduce ion conduction resistance in the solid electrolyte layer, it is preferable to form the solid electrolyte layer as thin as possible. On the other hand, if the solid electrolyte layer is formed to be thin, the strength of the solid electrolyte layer becomes small, and troubles occur in the manufacturing process or in use. For this reason, a structure (anode support structure) for securing the strength as a laminate by setting the thickness of the anode layer stacked on the solid electrolyte layer is often adopted.

As one technique for producing the above-described electrolyte-electrode laminate, it has been studied to thinly coat an electrolyte powder on an anode layer powder compact and sinter this electrolyte-anode laminate at the same time.

Japanese Laid-Open Patent Publication No. 2001-307546

By employing the above configuration, the strength of the electrolyte-anode laminate can be ensured while the thickness of the solid electrolyte layer is set to be small. However, when Ni is employed as the catalyst, there is a problem that the performance of the solid electrolyte layer is lowered during firing have.

For example, a powder of BaZrO ₃ -Y ₂ O ₃ (hereinafter referred to as BZY) is used as an electrolyte material, and nickel (Ni) or nickel oxide (NiO) is added to the BZY powder as an anode material There is a problem that the ion conductivity of the solid electrolyte layer tends to lower when the anode powder material added is used. Conventionally, the electrolyte-anode laminate is formed by applying the BZY powder onto the surface of a molded article obtained by compacting the anode powder material to a predetermined thickness and firing simultaneously at 1400 to 1600 캜. In this case, the inherent ion conductivity of the solid electrolyte layer made of BZY is impaired, and when it is applied to a fuel cell, the power generation performance is often lower than theoretically expected.

Although the details of the cause of the deterioration of the power generation performance are unknown, it can be inferred that the nickel added to the anode layer acts on the solid electrolyte layer to deteriorate the ion conductivity.

DISCLOSURE OF THE INVENTION The present invention is conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a fuel cell which can prevent the deterioration of the ion conductive performance of the solid electrolyte layer when the electrolyte- And a composite material for a fuel cell.

One aspect of the present invention is a composite material for a fuel cell comprising a solid electrolyte layer and an anode layer laminated on the solid electrolyte layer, wherein the solid electrolyte layer has a perovskite structure at the A site ( A-site) is composed of an ion conductor composed of at least one of barium (Ba) and strontium (Sr) and part of tetravalent cations of the B site substituted with a trivalent rare earth element, and the anode layer An electrolyte component having the same composition as that of the solid electrolyte layer and a nickel (Ni) catalyst, and an additive including a rare earth element at a boundary portion with at least the solid electrolyte layer.

By including the additive containing the rare earth element in the anode layer, the ion conductive performance of the solid electrolyte layer is not lowered even when the laminate composed of the solid electrolyte material and the anode material is simultaneously fired. It is possible to improve the power generation performance in one case.

In comparison with a noble metal such as platinum (Pt), inexpensive nickel is employed as a catalyst, and the ion conduction performance is not lowered even if the anode layer and the solid electrolyte layer are simultaneously fired.

1 is a cross-sectional view showing the structure of a composite material for a fuel cell according to an embodiment of the present invention.
2 is a schematic cross-sectional view of a fuel cell constructed using a composite material for a fuel cell according to an embodiment of the present invention.
Fig. 3 is a table comparing the configuration and power generation performance of a fuel cell constructed using the composite material for a fuel cell according to the present embodiment and a fuel cell constructed using a composite material for a fuel cell of the prior art.
FIG. 4 is a state diagram of an anode layer constituting material taken from JJ Lander, J. Am. Chem. Soc., 73, 2451 (1951).
5 is a three-dimensional state diagram of a green anode layer constituent material at 1000 ° C to 1350 ° C with reference to the state diagram described in J. Solid State Chem., 88 [1] 291-302 (1990).

(Mode for carrying out the invention)

[Discussion of Problems of Conventional Electrolyte-Anode Laminate]

The inventors of the present invention have made intensive studies on a conventional electrolyte-anode laminate and have obtained the following perceptions as to the cause of deterioration in ion conduction performance.

For example, in a conventional electrolyte-anode laminated body comprising a solid electrolyte layer made of BZY and an anode layer made of a material in which Ni is added to the BZY as a catalyst in the form of NiO, When the composition of the electrolyte layer is examined in detail, it has been found that the Ni component exists at a high concentration throughout the entire region of the solid electrolyte layer. Although it is clear that the Ni component is a catalyst component blended in the anode layer, it is unknown whether the Ni component migrated to the electrolyte layer and whether or not it interferes with the ion conductivity of the solid electrolyte layer.

Therefore, the inventors of the present invention have found that a fuel cell to which an electrolyte-anode laminate in which the movement of a Ni component to a solid electrolyte layer is suppressed and a concentration of a Ni component in the solid electrolyte layer is reduced, The power generating performance of the fuel cell having the laminate was compared. As a result, it has been found that power generation performance is improved by reducing the Ni component of the solid electrolyte layer.

[Outline of embodiment of the present invention]

One aspect of the present invention is a composite material for a fuel cell comprising a solid electrolyte layer and an anode layer laminated on the solid electrolyte layer, wherein the solid electrolyte layer has a structure in which the A site of the perovskite structure is barium Ba) and strontium (Sr), and an ion conductor in which a part of the tetravalent cation of the B site is substituted with a trivalent rare earth element, and the anode layer is made of the same material as the solid electrolyte layer And an additive including a rare earth element at a boundary portion with at least the solid electrolyte layer.

The addition amount of the additive including the rare earth element is preferably an atomic ratio of the rare earth element to the amount of the rare earth element in the solid electrolyte component contained in the anode layer is 0.001 to 2 times.

If the amount of the additive containing the rare earth element is less than 0.001 times the number of atoms of the rare earth element in the solid electrolyte component contained in the anode layer, the effect of preventing the decrease in ion conductivity hardly appears, Power generation performance can not be improved. On the other hand, when the addition amount of the additive including the rare earth element exceeds 2 times the amount of the rare earth element in the solid electrolyte component contained in the anode layer in terms of the number of atoms of the rare earth element, the affinity with the solid electrolyte layer is lowered So that the adhesion between the layers may be deteriorated or the composition of the solid electrolyte layer may be changed to lower the ion conductivity. It is more preferable that the addition amount of the additive including the rare earth element is 0.01 to 1.5 times the amount of rare earth element in the solid electrolyte component contained in the anode layer in terms of the number of atoms of the rare earth element. When the addition amount of the rare earth element is 0.01 times or more, the reaction inhibiting effect becomes remarkable. When the addition amount of the rare earth element is 1.5 times or less, the above-described interlayer adhesion is reduced, The effect is very small.

It is preferable that the anode layer is configured such that the ratio (B / A) of the number of atoms (B) of the Ni catalyst to the number of atoms (A) of the cation element other than the Ni catalyst is 0.5 to 10 . If the ratio of the number of atoms of the Ni catalyst and the other cation element is less than 0.5, sufficient catalytic effect can not be expected and the electron conductivity of the anode layer can not be ensured. On the other hand, if the ratio of the number of atoms of the Ni catalyst and the other cationic elements exceeds 10, the volume change during reduction from NiO to Ni becomes large, or the thermal expansion rate between the solid electrolyte layer and the anode layer becomes large, There is a fear that the electrolyte layer is broken or the amount of diffusion of Ni into the electrolyte layer is increased.

As the solid electrolyte constituting the solid electrolyte layer, yttrium-added barium zirconate may be employed, and an additive containing, for example, yttrium may be employed as the additive. As the additive containing yttrium, yttrium oxide (Y ₂ O ₃ ) or the like may be employed. The additive can be added to the entirety of the anode layer, and the effect can be expected by adding it to at least the boundary portion with the solid electrolyte layer. For example, an anode layer to which the additive is added may be formed between the solid electrolyte layer and the conventional anode layer.

The composite material for a fuel cell according to the present invention is characterized by comprising a laminate forming step of integrally laminating a powder material constituting the solid electrolyte layer and a powder material constituting the anode layer by thermally sintering the laminate, sintering the resulting mixture. In addition, in the step of forming the laminate, the anode layer may be formed in a form including the layer containing the additive formed on the side of the solid electrolyte and the two layers formed on the other side and not containing the additive have.

[Detailed Description of Embodiments of the Present Invention]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 is a cross-sectional view of a composite material for a fuel cell according to the present embodiment. The composite material 1 for a fuel cell according to the present embodiment is formed as an electrolyte-anode laminated body including the anode layer 2 and the solid electrolyte layer 3.

The solid electrolyte layer 3 is formed by firing a powder of yttrium-added barium zirconate (hereinafter referred to as BZY) which is a solid solution of barium zirconate (BaZrO ₃ ) and yttria (Y ₂ O ₃ ). The ratio of Zr to Y in the BZY is 8: 2, and the chemical formula of the solid solution powder is assumed to be Ba ₁₀ (Zr ₈ .Y ₂ ) O ₂₉ .

As the powder material for forming the anode layer 2 according to the present embodiment, a BZY powder as a constituent material of the solid electrolyte layer 3, a nickel oxide powder (hereinafter referred to as NiO) serving as a catalyst, and a rare earth element The Y ₂ O ₃ powder as an additive was adjusted so as to have a blending ratio (cation · at%) shown in FIG. On the other hand, as a comparative example, the material constituting the conventional anode layer was adjusted so as to be the mixing ratio shown in Fig. 3B. 3, the positive ions are Ba, Zr, Y, and Ni, and the at% represents the ratio of the numbers of atoms to the positive ions only. Further, for * 2 in Fig. 3, () indicates the content of Y atoms in BZY. The sample A according to the present embodiment is formed of a material in which a Y ₂ O ₃ powder of 2.8% is further blended instead of the BZY component of the anode material composed of the conventional component shown in the sample B.

20% by volume of polyvinyl alcohol (PVA) as a molding aid was added to these mixed powders, and the mixture was subjected to pressure molding with a diameter of 20 mm and a thickness of 2 mm by forming a uniaxial press, Molded article A and an anode formed article B according to a comparative example were respectively formed.

To the above BZY powder, an EC vehicle (EC Beikle Start 3-097, manufactured by Nisshin Chemical Industry Co., Ltd.) as a binder was added in an amount of 50 wt% of the BZY powder, and 2- (2-butoxyethoxy) A BZY powder slurry containing terpineol as a solvent was prepared. This BZY powder slurry is applied by screen printing to one side of the anode molding A and the anode molding B to a thickness of about 20 mu m to form a coating film constituting the solid electrolyte layer. Layer laminate according to Comparative Example B were formed.

These multilayered bodies were heated in the atmosphere at a temperature of 700 캜 for 24 hours to remove the resin component, and then heated in an oxygen atmosphere at a temperature of 1500 캜 for 10 hours and fired to obtain an electrolyte-anode laminate. The shrinkage rate accompanying firing was about 20%.

Quantitative analysis of the amount of Ni on the surface of the solid electrolyte layer opposite to the above-described anode layer was carried out by energy dispersive X-ray spectroscopy (EDX) in order to evaluate the reaction state between Ni and the solid electrolyte layer after firing. The results are shown in Fig. Ni of high concentration (2.2 at%: cation standard) was detected in Sample B (Comparative Example) formed of a material in which BZY and NiO were mixed in the same manner as in the prior art. In Sample A according to the present embodiment, (0.5 at%), and it was found that the addition of Y ₂ O ₃ suppressed the migration of Ni to the solid electrolyte layer 3.

The electrolyte-anode laminate was heated in an H ₂ atmosphere at a temperature of 700 ° C for 1 hour to reduce the anode layer and precipitate metallic Ni to obtain the composite material (1) for a fuel cell. A slurry of LSCF (La-Sr-Co-Fe-O) powder constituting the cathode layer was applied to the surface of the solid electrolyte layer 3 opposite to the anode layer 2, A cathode layer was formed to prepare an electrolyte-electrode laminate 11. The fuel cell 10 shown in Fig. 2 was constructed by using these electrolyte-electrode laminate 11.

The fuel cell 10 includes an electrolyte-electrode stack 11 supported at an intermediate portion of the tubular container 12 and having flow passages 13 and 14 for applying fuel gas to one side thereof , And flow paths (15, 16) for allowing air to act on the other side. Platinum meshes 19 and 20 are formed as collectors on the surface of the anode electrode and the surface of the cathode of the electrolyte-electrode laminate 11. The platinum meshes 19 and 20 are formed on the outside And lead wires 17 and 18 that are drawn out are connected, respectively.

In the fuel cell 10, hydrogen is flowed at 20 to 100 cc / mn as fuel gas to act on the anode, and air is caused to flow at 20 to 100 cc / min to act on the cathode, Power generation performance was measured.

As shown in FIG. 3, in the fuel cell having the electrolyte-electrode laminate formed of the sample A as the composite material according to the present embodiment, the power generation performance of 100 mW / cm 2 was obtained, In the fuel cell having the electrolyte-electrode laminate formed of the sample B, only the power generation performance of 30 mW / cm < 2 > was exhibited and the electrolyte-electrode laminate formed of the sample A of the present embodiment It has been found that the fuel cell constituted exerts a high power generation performance.

[Investigation of the Movement of Ni Component and Causes of Inhibition of Ionic Conductivity in Conventional Composite Material for Fuel Cell (Electrode Anode Laminate)] [

The reason why the Ni component in the solid electrolyte layer diffuses to a considerable extent in the conventional electrolyte-anode laminate and the working mechanism of the present invention have been discussed from the viewpoint of the kinetic point of view and the thermodynamic point of view.

The inventors of the present invention have hypothesized that the Ni component in the calcination process has become a liquid phase and has migrated to the entire solid electrolyte layer due to capillary phenomenon or the like. This is because it is considered that the movement by the liquid phase is significantly higher than the movement by the solid diffusion.

The conventional anode layer is formed by mixing powder of BZY powder and NiO powder, and it is considered that the following reaction occurs in the firing process.

(Scheme 1)

Ba ₁₀ (Zr ₈ Y ₂ ) O ₂₉ + 2NiO-> Ba ₈ Zr ₈ O ₂₄ + Y ₂ BaNiO ₅ + BaNiO ₂

Fig. 4 shows a state diagram of the BaO-NiO-based compound. As is apparent from this figure, it is found that the melting point of the BaO-NiO-based compound is about 1100 to 1200 占 폚, and the temperature of the liquid phase is lowered in the vicinity of the mixing ratio of BaO and NiO being 1: The composition BaNiO ₂ estimated from the reaction formula 1 also has a molar ratio of BaO to NiO of 50%, and consequently, it is presumed that BaNiO ₂ or a Ni-containing compound close to it is produced at a firing temperature of 1500 ° C to form a liquid phase can do. It is presumed that the BaNiO ₂ or the Ni-containing compound which has become the liquid phase migrates by the capillary phenomenon or the like the pores of the solid electrolyte layer in the firing process and exists in the entire solid electrolyte layer. The above-mentioned BaNiO ₂ or a Ni-containing compound close to it is precipitated in the grain boundaries of the solid electrolyte layer in the solidification process or the like, and Ni is dissolved in the BZY lips, and the ionic conductivity between the boundaries in the solid electrolyte layer And the like.

On the basis of the above recognition, the inventors of the present invention have assumed that the movement of the Ni component to the solid electrolyte layer can be suppressed by inhibiting liquefaction of the Ni-containing compound, and as a result of repeating the experiment, It came to the following.

[Consideration of the action and effect of the composite material (electrolyte-anode laminate for fuel cell) according to the embodiment of the present invention]

In this embodiment, in order to inhibit the formation of BaNiO ₂ in Reaction Scheme 1, an additive containing a rare-earth element is added to the powder material constituting the anode layer and fired.

As an anode layer, a case in which NiO is added as a catalyst component to the powder made of BZY, and Y ₂ O ₃ is further added as the above additive and calcined.

When it is assumed that Y ₂ BaNiO ₅ is produced instead of BaNiO ₂ , the amount of Y ₂ O ₃ added is the same as the amount of Y ₂ O ₃ contained in BZY in the anode layer at the maximum. For example, when 20 at% of Zr in BaZrO ₃ is substituted with Y, it is considered that the reaction formula with NiO becomes as follows by addition of Y ₂ O ₃ .

(Scheme 2)

Ba ₁₀ (Zr ₈ Y ₂ ) O ₂₉ + 2NiO + Y ₂ O ₃ ? Ba ₈ Zr ₈ O ₂₄ + 2Y ₂ BaNiO ₅

When Y ₂ O ₃ is added to the anode layer to cause the reaction shown in the above reaction formula, BaNiO ₂ produced in the reaction formula 1 is not produced. Further, when this amount of Y ₂ O ₃ is added, BaNiO ₂ is not produced even if the entire amount of Y in BZY reacts with NiO together with Ba.

In the three-way state diagram shown in Figure 5, the idea that area indicated by A2 is, Y ₂ O ₃ is not is not added, and corresponds to a region in which the liquidus temperature indicated by A1 in Fig. 4 largely reduced, the liquid phase is generated do. In addition, the material constituting the conventional anode layer is a composition which forms a grain boundary of a composition represented by C2 when the whole amount of Y in BZY flows out of the grains together with Ba and reacts with NiO, It can be assumed that the Ba-Ni-O compound is in a liquid state together with BaY ₂ NiO ₅ Ni.

On the other hand, in the present embodiment, since Y ₂ O ₃ is added, it is considered that the compound BaY ₂ NiO ₅ in the region of D ₂ in the three-dimensional state diagram is generated. The BaY ₂ NiO ₅ has a high melting point and can be assumed to be in a solid-phase state even at a temperature of 1500 ° C.

As a result, it is possible to prevent the Ni-containing compound that is generated in the firing process from becoming a liquid phase, and to prevent the movement of the Ni component from the anode layer to the solid electrolyte layer. On the other hand, from the thermodynamic point of view, it is presumed that, with the addition of Y ₂ O ₃ to the anode layer, the chemical potential of Y of the anode layer rises and the outflow of Y from the BYZ in the anode layer is suppressed. Since the outflow of Ba is not likely to occur when it is not concurrent with the cation of the B site, it is consequently linked to inhibition of the outflow of Y and Ba out of the BZY grains, that is, the reaction of Y, Ba and NiO .

The amount of Y ₂ O ₃ to be added is preferably a large amount from the viewpoint of suppressing the formation of a liquid phase, but is preferably small from the viewpoint of maintaining the affinity of the solid electrolyte layer for BZY and the influence on the anode layer. When the addition amount of Y ₂ O ₃ is less than 0.001 times the amount of the rare earth element in the electrolyte component contained in the anode layer by the number of atoms of the rare earth element, the liquid phase formation inhibiting effect is small. On the other hand, if it is more than 2 times, the affinity with the solid electrolyte layer is lowered and the adhesion between the layers is lowered, or the ratio of Zr: Y of the electrolyte is changed, and ion conductivity may be lowered. It is more preferable that the amount of the Y ₂ O ₃ added is 0.01 to 1.5 times the amount of rare earth elements in the solid electrolyte component contained in the anode layer in terms of the number of atoms of the rare earth element.

When the addition amount of Y ₂ O ₃ is 0.01 times or more, the reaction inhibiting effect becomes remarkable. When the addition amount of the additive containing rare-earth element is 1.5 times or less, the above-described interlayer adhesion force is lowered and the influence on the composition of the solid electrolyte layer It is very small.

In addition, even when the composite material according to A (the present embodiment) in Fig. 3 is used, Ni of 0.1 at% is detected from the solid electrolyte layer, but it is considered that the amount of movement is small and the ion conductivity is not greatly disturbed.

The present embodiment is also applied to the case where the A site of the perovskite structure is composed of barium Ba and has a solid electrolyte layer composed of an ion conductor in which a part of the tetravalent cation of the B site is replaced by yttrium The present invention can be applied to an ion conductor made of strontium (Sr) or barium (Ba) and strontium (Sr) as the A site as the solid electrolyte layer. In the present embodiment, Y ₂ O ₃ is added to the entire anode layer, but an additive containing a rare earth element can be added to at least a boundary portion with the solid electrolyte layer. For example, a layer to which Y ₂ O ₃ is added may be formed separately at the boundary portion.

The scope of the present invention is not limited to the above-described embodiments. It should be understood that the presently disclosed embodiments are illustrative in all respects and are not restrictive. The scope of the present invention is not limited to the above-mentioned meanings, but is expressed by the claims, and is intended to include all modifications within the scope and meaning equivalent to the claims.

It is possible to provide an electrolyte-anode laminate capable of constituting a fuel cell having high generating performance at low cost.

1: electrolyte-anode laminate (composite material for fuel cell)
2: anode layer
3: solid electrolyte layer
10: Fuel cell
11: Electrolyte-electrode laminate
12: tubular container
13: Flow path (fuel gas)
14: Flow path (fuel gas)
15: Flow path (air)
16: Flow path (air)
17: lead wire
18: lead wire
19: Platinum mesh
20: Platinum Messe

Claims (7)

1. A composite material for a fuel cell comprising a solid electrolyte layer and an anode layer laminated on the solid electrolyte layer,
In the solid electrolyte layer, the A site of the perovskite structure is composed of at least one of barium (Ba) and strontium (Sr), and a part of the tetravalent cation of the B site is replaced with a trivalent rare earth element And the ion conductor is replaced with an ion conductor,
Wherein the anode layer comprises an electrolyte component having the same composition as the solid electrolyte layer and a nickel (Ni) catalyst, and includes an additive containing a rare earth element at a boundary portion with at least the solid electrolyte layer A composite material for a fuel cell. The method according to claim 1,
Wherein the amount of the additive including the rare earth element is 0.001 to 2 times the amount of the rare earth element in the electrolyte component contained in the anode layer in terms of the number of atoms of the rare earth element. The method according to claim 1,
Wherein the amount of the additive including the rare earth element is 0.01 to 1.5 times the amount of the rare earth element in the solid electrolyte component contained in the anode layer in terms of the number of atoms of the rare earth element. 4. The method according to any one of claims 1 to 3,
Wherein the anode layer has a ratio (B / A) of the number of atoms (B) of the Ni catalyst to the number of atoms (A) of the cation element other than the Ni catalyst of 0.5 to 10.0. 5. The method according to any one of claims 1 to 4,
Wherein the solid electrolyte constituting the solid electrolyte layer is yttrium-added barium zirconate (BaZrO ₃ -Y ₂ O ₃ )
Wherein the additive containing the rare earth element comprises yttrium (Y). A method for producing a composite material for a fuel cell according to any one of claims 1 to 5,
A laminate forming step of integrally laminating a powder material constituting the solid electrolyte layer and a powder material constituting the anode layer,
And a firing step of thermally sintering the laminate. A fuel cell comprising the composite material for a fuel cell according to claim 1.

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